## Gurukul Vidyapeeth Institute of Engineering and Technology Rajpura Patiala

Gurukul Vidyapeeth Institute of Engineering and Technology is situated in the district Patiala (Punjab) of India.

Affiliated with: Punjab Technical University (PTU), Kapurthala

Approved by: All India Council for Technical Education (AICTE), New Delhi.

Courses offered:

B.Tech.

• Computer Science Engineering
• Electronics and Communication Engineering
• Mechanical Engineering
• Information Technology
• Civil Engineering
• Aeronautical Engineering
• Chemical Engineering

10+2 Non-Medical (PCM) passed.

Total seats are classified in 2 categories. Institute can fill 33% of the seats (Management Quota) directly provided the students possess requisite qualification. Balance (67%) seats are filled through counseling conducted by PTU on the basis of ranking in All India Engineering Entrance Exam (AIEEE).

Other courses: M.Tech., MBA, PGDM, BBA, BCA, MSc (IT), B.Sc.(IT)

Website: www.gurukul.cc

Email : info@gurukul.cc

Gurukul Vidyapeeth Institute of Engineering and Technology (South campus)

Chandigarh-Patiala Highway

Ramnagar

Banur

Tehsil- Rajpura

District: Patiala-

Punjab,

INDIA

Phone : 0172-3296969

Gurukul Vidyapeeth Institute of Engineering and Technology (North campus)

Chandigarh-Patiala Highway

Ramnagar

Banur

Tehsil- Rajpura

District: Patiala-

Punjab,

INDIA

Phone : 0172-3296969

## Maxwell third equation and its derivation

Statement.(a)  It states that,whenever magnetic flux linked with a circuit changes then induced electromotive force (emf) is set up in the circuit. This induced emf lasts so long as the change in magnetic flux continues.

(b) The magnitude of induced emf is equal to the rate of change of magnetic flux linked with the circuit.

Therefore                               induced emf= – dφm/dt Continue reading “Maxwell third equation and its derivation”

## Maxwells first and second equations and their derivation

Maxwell’s first equation or Gauss’s law in electrostatics

Statement. It states that the total electric flux φE passing through a closed hypothetical surface is equal to 1/ε0 times the net charge enclosed by the surface:

ΦE=∫E.dS=q/ε0

∫D.dS=q

where D=ε0E= Displacement vector Continue reading “Maxwells first and second equations and their derivation”